Pipe with rib and method for manufacturing pipe with rib

ABSTRACT

A pipe with a rib includes a pipe portion, and a rib portion formed inside the pipe portion. The rib portion includes a plurality of bent portions in accordance with bending of the pipe portion.

The disclosure of Japanese Patent Application No. 2012-240826 filed onOct. 31, 2012 including the specification, drawings and abstract isincorporated herein by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a pipe with a rib, and a method formanufacturing the pipe with a rib.

2. Description of Related Art

In Japanese Patent Application Publication No. 2012-61518 (JP 2012-61518A), a free casting method is proposed as an up-drawing continuouscasting method that does not require a mold. As described in JP2012-61518 A, after a starter is immersed into a surface of molten metal(or a molten metal surface), the starter is drawn up, and then, themolten metal is also drawn out following the starter by a surface filmand surface tension of the molten metal. Here, the molten metal is drawnout through a shape defining member placed near the molten metalsurface, and then cooled. This way, continuous casting of a castinghaving a desired sectional shape is achieved.

In an usual continuous casting method, a shape in a longitudinaldirection, as well as a sectional shape, are defined by a mold. In acontinuous casting method in particular, solidified metal (or a casting)needs to pass through inside of a mold. Therefore, a casting that hasbeen cast has a shape that extends linearly in a longitudinal direction.On the contrary, in a free casting method, a shape defining memberdefines only a sectional shape of a casting, and does not define a shapein a longitudinal direction. Since the shape defining member is able tomove in a direction parallel to a molten metal surface (or a horizontaldirection), castings with various longitudinal shapes are obtained. Forexample, JP 2012-61518 A describes a hollow casting (or a pipe) formedinto a zigzag or helical shape, instead of a linear shape, in alongitudinal direction.

The inventors have found out the followings. With conventional methodsincluding extrusion molding, press forming, welding, cutting, metal moldcasting, and so on, it has been extremely difficult to manufacture apipe that has a rib inside and is non-linearly shaped.

SUMMARY OF THE INVENTION

The present invention provides a pipe that has a rib inside and isnon-linearly shaped.

A pipe with a rib according to a first aspect of the present inventionincludes a pipe portion, and a rib portion formed inside the pipeportion. The rib portion has a plurality of bent portions in accordancewith bending of the pipe portion.

In the first aspect, the pipe with the rib may be a continuous casting.Also, the plurality of bent portions may be formed continuously. Theplurality of bent portions may be structured so that the adjacent bentportions are bent in opposite directions to each other. Further, the ribportion may further include a twisted portion formed in accordance withtwisting of the pipe portion. It has been even more difficult tomanufacture such a pipe with a rib by conventional methods.

A pipe with a rib according to a second aspect of the present inventionincludes a pipe portion, and a rib portion formed inside the pipeportion. The rib portion includes a twisted portion in accordance withtwisting of the pipe portion.

In the second embodiment, the pipe with the rib may be a continuouscasting.

A method for manufacturing a pipe with a rib according to a third aspectof the present invention is a method for manufacturing a pipe with arib, in which a rib portion formed inside a pipe portion includes aplurality of bent portions in accordance with bending of the pipeportion. The manufacturing method includes drawing out molten metal heldin a molten metal holding furnace by using a starter, from a surface ofthe molten metal, and drawing up the molten metal through a shapedefining member that defines a sectional shape of the pipe with the ribto be cast, and cooling and solidifying the molten metal that has passedthrough the shape defining member and been drawn up. The plurality ofbent portions are formed by moving at least either one of the starterand the shape defining member in a horizontal direction.

According to the third aspect, it is possible to manufacture a pipe witha rib which has been extremely difficult to manufacture by conventionalmethods including extrusion molding, press forming, welding, cutting,metal mold casting, and so on.

In the third aspect, cooling gas may be introduced to an inner side ofthe pipe with the rib to be cast, and an opening may be provided in thestarter.

A method for manufacturing a pipe with a rib according to a fourthaspect of the present invention is a method for manufacturing a pipewith a rib in which a rib portion formed inside a pipe portion includesa twisted portion in accordance with twisting of the pipe portion. Themanufacturing method includes drawing out molten metal held in a moltenmetal holding furnace by using a starter, from a surface of the moltenmetal, and drawing up the molten metal through a shape defining memberthat defines a sectional shape of the pipe with the rib to be cast, andcooling and solidifying the molten metal that has passed through theshape defining member and been drawn up. The twisted portion is formedby rotating at least either one of the starter and the shape definingmember about an axis that extends along a vertical direction.

According to the fourth aspect, it is possible to manufacture a pipewith a rib which has been extremely difficult to manufacture byconventional methods including extrusion molding, press forming,welding, cutting, metal mold casting, and so on.

In the fourth aspect, cooling gas may be introduced to an inner side ofthe pipe with the rib to be cast, and an opening may be provided in thestarter.

According to the first to fourth aspects, it is possible to provide apipe that has a rib inside and is non-linearly shaped.

BRIEF DESCRIPTION OF THE DRAWINGS

Features, advantages, and technical and industrial significance ofexemplary embodiments of the invention will be described below withreference to the accompanying drawings, in which like numerals denotelike elements, and wherein:

FIG. 1 is a sectional view of a free casting apparatus according to afirst embodiment of the present invention;

FIG. 2 is a plan view of inner shape defining members and an outer shapedefining member of the free casting apparatus;

FIG. 3 is a cross-sectional view of a casting according to the firstembodiment;

FIG. 4A and FIG. 4B are photographs showing external appearance of anexample of the casting according to the first embodiment, and FIG. 4C isan X-ray photograph of bent portions of the casting;

FIG. 5 is a photograph showing external appearance of another example ofthe casting according to the first embodiment; and

FIG. 6A is a photograph showing external appearance of an example of acasting according to a second embodiment of the present invention, andFIG. 6B is an X-ray photograph of a twisted portion of the casting.

DETAILED DESCRIPTION OF EMBODIMENTS

Herein below, specific embodiments, to which the present invention isapplied, will be explained in detail with reference to the drawings. Itshould be noted, however, that the present invention is not limited tothe embodiments described below. Also, statements and drawings below aresimplified as necessary in order to clarify the explanation.

First Embodiment

First, a free casting apparatus (an up-drawing continuous castingapparatus) according to a first embodiment will be explained withreference to FIG. 1. FIG. 1 is a sectional view of a free castingapparatus according to the first embodiment. As shown in FIG. 1, thefree casting apparatus according to the first embodiment includes amolten metal holding furnace 101, inner shape defining members 102 a, anouter shape defining member 102 b, inner cooling gas nozzles 103, asupport rod 104, an actuator 105, and outer cooling gas nozzles 106.

The molten metal holding furnace 101 holds molten metal M1 such asaluminum and an aluminum alloy, and keeps the molten metal M1 atpredetermined temperature. In the example shown in FIG. 1, since themolten metal is not replenished in the molten metal holding furnace 101during casting, a surface of the molten metal M1 (or a molten metalsurface) is lowered along with a progress of casting. However, themolten metal may be replenished into the molten metal holding furnace101 as necessary during casting so that the molten metal surface is keptconstant. As a matter of course, the molten metal M1 may be other metalor an alloy than aluminum.

The inner shape defining members 102 a and the outer shape definingmember 102 b are made of, for example, ceramics or stainless steel, andarranged near the molten metal surface. In the example shown in FIG. 1,four inner shape defining members 102 a and one outer shape definingmember 102 b are arranged so as to be in contact with the molten metalsurface. However, the inner shape defining members 102 a and the outershape defining member 102 b may be arranged so that main surfaces of theinner shape defining members 102 a and the outer shape defining member102 b on lower sides (a molten metal surface side) do not come intocontact with the molten metal surface. To be specific, a predeterminedgap (of, for example, approximately 0.5 mm) may be provided between themolten metal surface and, the main surfaces of the inner shape definingmembers 102 a and the outer shape defining member 102 b on the lowerside. The four inner shape defining members 102 a define an inner shapeof a casting M3 to be cast, and the outer shape defining member 102 bdefines an outer shape of the casting M3 to be cast.

FIG. 2 is a planar view of the inner shape defining members 102 a andthe outer shape defining member 102 b. The sectional view of the innershape defining members 102 a and the outer shape defining member 102 bin FIG. 1 is equivalent to a sectional view taken along a line I-I inFIG. 2. As shown in FIG. 2, the outer shape defining member 102 b has,for example, a rectangular planar shape, and has a square opening in thecenter. The four inner shape defining members 102 a have square planarshapes that are congruent with each other, and are arrayed in a 2×2matrix in the opening of the outer shape defining member 102 b. A gapbetween the inner shape defining members 102 a and the outer shapedefining member 102 b serves as a molten metal passage portion 102 cthrough which the molten metal passes. As described above, the innershape defining members 102 a, the outer shape defining member 102 b, andthe molten metal passage portion 102 c structure a shape defining member102.

As shown in FIG. 1, the molten metal M1 is drawn up following thecasting M3 by a surface film and surface tension of the molten metal M1,and passes through the molten metal passage portion 102 c. The moltenmetal, which is drawn up from the molten metal surface following thecasting M3 by a surface film and surface tension of the molten metal,will be referred to as “retained molten metal M2”. An interface betweenthe casting M3 and the retained molten metal M2 is a solidificationinterface.

The four inner cooling gas nozzles (inner cooling parts) 103 areconnected to center parts of the inner shape defining members 102 a,respectively, and support the inner shape defining members 102 a. At thesame time, each of the inner cooling gas nozzles 103 blows cooling gas(such as air, nitrogen, argon) on the casting M3 from the center partsof the corresponding inner shape defining member 102 a, thus cooling thecasting M3 from inside. The support rod 104 supports the outer shapedefining member 102 b. A positional relation between the inner shapedefining members 102 a and the outer shape defining member 102 b ismaintained by the inner cooling gas nozzles 103 and the support rod 104.

The four inner cooling gas nozzles 103 and the support rod 104 areconnected to the actuator 105. Due to the actuator 105, the four innercooling gas nozzles 103 and the support rod 104 are able to move in avertical direction (a perpendicular direction) and a horizontaldirection (parallel to the molten metal surface) while maintaining thepositional relation between the inner shape defining members 102 a andthe outer shape defining member 102 b. With such a structure, it ispossible that the inner shape defining members 102 a and the outer shapedefining member 102 b are moved in a downward direction as the moltenmetal surface is lowered along with progress of casting. Also, since theinner shape defining members 102 a and the outer shape defining member102 b are able to move in the horizontal direction, a shape of thecasting M3 in the longitudinal direction is freely changeable.

The outer cooling gas nozzles (outer cooling parts) 106 is designed toblow cooling gas (such as air, nitrogen, and argon) on the casting M3and cool the casting M3. The casting M3 is cooled by the cooling gaswhile the casting M3 is drawn up by a lifting device (not shown)connected to a starter ST. Thus, the retained molten metal M2 near thesolidification interface is solidified sequentially, thereby forming thecasting M3.

Next, the casting M3 will be explained with reference to FIG. 3 and FIG.

4A to FIG. 4C. FIG. 3 is a sectional view of the casting M3 according tothe first embodiment, taken along a horizontal plane. As shown in FIG.3, the casting M3 is a hollow casting (or a pipe), a section of whichtaken along the horizontal plane (referred to as a “transverse plane”herein below) has a cross inside a square shape. In other words, thecasting M3 includes a pipe portion M31 having a square-shaped section,and a rib portion M32 that is formed inside the pipe portion M31 and hasa cross-shaped section. The sectional shapes of the pipe portion M31 andthe rib portion M32 are not limited at all. For example, the sectionalshape of the pipe portion M31 may be a circular shape, an ellipticalshape, a triangle, a polygon such as a pentagon or above, and so on.There is also no limit on the number and the sectional shape of the ribportion M32. It is also possible to change the sectional shape of thecasting M3 while casting.

FIG. 4A and FIG. 4B are photographs showing external appearance of anexample of the casting M3 according to the first embodiment, and FIG. 4Cis an X-ray photograph of bent portions. FIG. 4A is a photograph showingexternal appearance of an example of the whole casting M3 in thelongitudinal direction according to the first embodiment. A left side ofthe photograph in FIG. 4A is an upper side of the casting M3, and aright side of the photograph is a lower side of the casting M3. Thecasting M3 shown in FIG. 4A includes five bent portions formedcontinuously. FIG. 4B is a photograph showing external appearance of thecasting M3 seen from obliquely above. The casting M3 is made of analuminum alloy A6063, and has a section having a cross inside a squareshape with a thickness of 1.5 to 2.5 mm (a gap in the molten metalpassage portion 102 c is 3.0 mm). FIG. 4C is an X-ray photograph showingthe five bent portions from the side. The bent portions werephotographed by using a digital X-ray sensor NX-06 and a portable X-rayphotographic apparatus PX-20HF, made by RF Co., Ltd., under conditionswith tube voltage of 74 kVp and tube current time of 25 mAs. As shown inFIG. 4C, the pipe portion M31 of the casting M3 includes the five bentportions 11 to 15. The bent portions adjacent to each other are bent indirections opposite to one another. To be more specific, the bentportions 11, 13, and 15 are bent in the same direction. Also, the bentportions 12 and 14 are bent in the same direction. The bent portions 11,13, and 15, and the bent portions 12 and 14 are bent in the oppositedirections to each other. Further, as shown in FIG. 4C, the rib portionM32 includes five bent portions 21 to 25 corresponding to the five bentportions 11 to 15 of the pipe portion M31. The number of the bentportions can be any number.

As explained above, the casting M3 according to the first embodiment isa pipe with a rib, which includes the pipe portion M31, and the ribportion M32 formed inside the pipe portion M31. In the pipe portion M31,the plurality of bent portions, which are bent in opposite directions toeach other, are formed continuously. In the rib portion M32, the bentportions corresponding to the bent portions of the pipe portion M31 arealso formed. It has been difficult to manufacture a pipe with a ribhaving the above-mentioned shape by conventional methods includingextrusion molding, press forming, welding, cutting, metal mold casting,and so on, and a combination of these methods. In other words, in thefree casting method according to the first embodiment, it is possible tomanufacture a pipe with a rib having a shape, which has not been able tobe manufactured by the conventional methods and a combination of theconventional methods. The pipe with the rib may be used for, forexample, a heat exchanger. Details of the free casting method accordingto the first embodiment will be explained later.

FIG. 5 is a photograph showing external appearance of another example ofthe casting M3 according to the first embodiment. A total length of thecasting M3 shown in FIG. 5 is as large as 1200 mm. As shown in FIG. 5,in the free casting method according to the first embodiment, it ispossible to form various bent portions continuously or intermittently.Also, since cooling gas is introduced into the casting M3 through theinner cooling gas nozzles 103, an opening for leading out the coolinggas is provided in the starter ST.

Next, the free casting method according to the first embodiment will beexplained with reference to FIG. 1. First, the starter ST is lowered sothat the starter ST passes through the molten metal passage portion 102c between the inner shape defining members 102 a and the outer shapedefining member 102 b, and a tip end of the starter ST is immersed intothe molten metal Ml. It is preferred that a starter to be used as thestarter ST has a same sectional shape as the casting M3, and extendslinearly in the longitudinal direction.

Next, the starter ST starts to be drawn up at a predetermined speed.Here, even if the starter ST is separated from the molten metal surface,the retained molten metal M2 is formed, which follows the starter ST andis drawn up from the molten metal surface by the surface film andsurface tension. As shown in FIG. 1, the retained molten metal M2 isformed in the molten metal passage portion 102 c between the inner shapedefining members 102 a and the outer shape defining member 102 b. Thismeans that the inner shape defining members 102 a and the outer shapedefining member 102 b give the retained molten metal M2 a shape.

Next, because the starter ST is cooled by the cooling gas blown out fromthe inner cooling gas nozzles 103 and the outer cooling gas nozzles 106,the retained molten metal M2 is sequentially solidified from the upperside towards the lower side, and the casting M3 thus grows. This way,continuous casting of the casting M3 is achieved. In addition, it ispossible to give the casting M3 the bent portions by moving the innershape defining members 102 a and the outer shape defining member 102 bin the horizontal direction. Instead of moving the inner shape definingmembers 102 a and the outer shape defining member 102 b in thehorizontal direction, the starter ST fixed to the lifting device may bemoved in the horizontal direction. Alternatively, the inner shapedefining members 102 a and the outer shape defining member 102 b, andthe starter ST may be moved in opposite directions to each other withina horizontal plane.

Second Embodiment

A casting M3 according to a second embodiment will be explained withreference to FIG. 6A and FIG. 6B. FIG. 6A is a photograph showingexternal appearance of an example of the casting M3 according to thesecond embodiment, and FIG. 6B is an X-ray photograph of a twistedportion. The casting M3 shown in FIG. 6A includes a twisted portion 31.The casting M3 is also made of an aluminum alloy A6063 and has a sectionhaving a cross inside a square shape with a thickness of 1.5 to 2.5 mm(a gap in the molten metal passage portion 102 c is 3.0 mm). FIG. 6B isan X-ray photograph of the twisted portion 31 seen from above. Thetwisted portion was photographed by using a digital X-ray sensor NX-06and a portable X-ray photographic apparatus PX-20HF, made by RF Co.,Ltd., under conditions with tube voltage of 74 kVp and tube current timeof 25 mAs. As shown in FIG. 6B, in the twisted portion 31, a pipeportion M31 and a rib portion M32 are both twisted about a longitudinaldirection of the casting M3.

In a free casting method according to the second embodiment, an innershape defining members 102 a and an outer shape defining member 102 bare rotated about an axis that extends along a vertical direction inorder to give the casting M3 the twisted portion 31. Instead of theinner shape defining members 102 a and the outer shape defining member102 b, a starter ST fixed to a lifting device may be rotated about theaxis that extends along the vertical direction. Alternatively, innershape defining members 102 a and an outer shape defining member 102 b,and the starter ST may be rotated in opposite directions to each otherabout the axis that extends along the vertical direction.

As stated above, the casting M3 according to the second embodiment is apipe with a rib, which includes the pipe portion M31, and the ribportion M32 formed inside the pipe portion M31. The casting M3 accordingto the second embodiment has the twisted portion 31 in which the pipeportion M31 and the rib portion M32 are twisted together about thelongitudinal direction of the casting M3. It has been difficult tomanufacture a pipe with a rib having the above-mentioned shape byconventional methods including extrusion molding, press forming,welding, cutting, metal mold casting, and so on, and a combination ofthese methods. In other words, in the free casting method according tothe second embodiment, it is possible to manufacture a pipe with a ribhaving a shape, which has not been able to be manufactured by theconventional methods and a combination of the conventional methods. Thepipe with the rib may be used for, for example, a heat exchanger. Due toan anchor effect of the twisted portion 31, for example, the casting M3is easily fixed in the ground.

The present invention is not limited to the foregoing embodiments, andmay be changed as appropriate without departing from the scope of theinvention. In particular, the first embodiment and the second embodimentmay be combined. In other words, the casting M3 may be a pipe with a ribhaving both the plurality of bent portions and the twisted portion.

What is claimed is:
 1. A pipe with a rib, comprising: a pipe portion;and a rib portion formed inside the pipe portion, wherein the ribportion includes a plurality of bent portions in accordance with bendingof the pipe portion.
 2. The pipe with the rib according to claim 1,wherein the pipe with the rib is a continuous casting.
 3. The pipe withthe rib according to claim 1, wherein the plurality of bent portions areformed continuously.
 4. The pipe with the rib according to claim 3,wherein the plurality of bent portions are structured so that theadjacent bent portions are bent in opposite directions to each other. 5.The pipe with the rib according to claim 1, wherein the rib portionfurther includes a twisted portion that is formed in accordance withtwisting of the pipe portion.
 6. A pipe with a rib, comprising: a pipeportion; and a rib portion formed inside the pipe portion, wherein therib portion includes a twisted portion in accordance with twisting ofthe pipe portion.
 7. The pipe with the rib according to claim 6, whereinthe pipe with the rib is a continuous casting.
 8. A method formanufacturing a pipe with a rib, in which a rib portion formed inside apipe portion includes a plurality of bent portions in accordance withbending of the pipe portion, comprising: drawing out molten metal heldin a molten metal holding furnace by using a starter, from a surface ofthe molten metal, and drawing up the molten metal through a shapedefining member that defines a sectional shape of the pipe with the ribto be cast; and cooling and solidifying the molten metal that has passedthrough the shape defining member and been drawn up, wherein theplurality of bent portions are formed by moving at least either one ofthe starter and the shape defining member in a horizontal direction. 9.The method for manufacturing a pipe with a rib according to claim 8,wherein cooling gas is introduced to an inner side of the pipe with therib to be cast, and an opening is provided in the starter.
 10. A methodfor manufacturing a pipe with a rib, in which a rib portion formedinside a pipe portion includes a twisted portion in accordance withtwisting of the pipe portion, comprising: drawing out molten metal heldin a molten metal holding furnace by using a starter, from a surface ofthe molten metal, and drawing up the molten metal through a shapedefining member that defines a sectional shape of the pipe with the ribto be cast; and cooling and solidifying the molten metal that has passedthrough the shape defining member and been drawn up, wherein the twistedportion is formed by rotating at least either one of the starter and theshape defining member about an axis that extends along a verticaldirection.
 11. The method for manufacturing a pipe with a rib accordingto claim 10, wherein cooling gas is introduced to an inner side of thepipe with the rib to be cast, and an opening is provided in the starter.